A mount for a peripheral device including a first plate having an opening; a second plate coupled to the first plate via a first hinged joint so as to be pivotable between a closed configuration and an open configuration; and a levelling plate disposed in the opening and coupled to the first plate via a second hinged joint so as to be pivotable between a flushed configuration and an angled-off configuration. The first hinged joint and the second hinged joint being parallel and at opposite portions of the first plate. A free end of the second plate in the closed configuration and a free end of the levelling plate in the flushed configuration are directed in opposite directions along the first plate. The levelling plate includes a socket structure to receive an attachment assembly for attaching the peripheral device to the levelling plate. The first plate includes a lip portion.

A mounting system is disclosed that includes a bracket configured to mount an object on a structure. The bracket includes a front panel, two side panels extending from the front panel, and a plurality of slots. Each slot is configured to accept a projection connected to the object and retain the projection within the slot. The bracket further includes a plurality of apertures. The mounting system further includes a retainer configured to extend into the bracket through the plurality of apertures and prevent, at least in part, the plurality of projections, retained by the bracket in the plurality of slots, from being withdrawn from the plurality of slots.

A mounting system is disclosed that includes a bracket configured to mount an object on a structure. The bracket includes a front panel, two side panels extending from the front panel, and a plurality of slots. Each slot is configured to accept a projection connected to the object and retain the projection within the slot. The bracket further includes a plurality of apertures. The mounting system further includes a retainer configured to extend into the bracket through the plurality of apertures and prevent, at least in part, the plurality of projections, retained by the bracket in the plurality of slots, from being withdrawn from the plurality of slots.

A ratcheting device according to the solution comprises a rotatable cogwheel comprising a plurality of teeth, a spring-loaded primary pawl, a spring-loaded handle pawl, a handle comprising a handle pawl disengagement lever, a handle pawl disengagement plate and a primary pawl disengagement plate. The primary pawl disengagement plate is mechanically coupled to the handle such that the handle may be rotated around the cogwheel to a point that the primary pawl disengagement plate contacts the spring-loaded primary pawl and causes it to disengage from the cogwheel. At the same time that the primary pawl is disengaged from the cogwheel teeth by the primary pawl disengagement plate, the handle pawl is similarly disengaged from the cogwheel teeth via contact with a handle pawl disengagement plate. Advantageously, the ratcheting device may be transitioned between a ratcheting state and a free-to-rotate state with only a single hand of the user and without requiring the handle to travel beyond a 180-degree arc of motion.

A ratcheting device according to the solution comprises a rotatable cogwheel comprising a plurality of teeth, a spring-loaded primary pawl, a spring-loaded handle pawl, a handle comprising a handle pawl disengagement lever, a handle pawl disengagement plate and a primary pawl disengagement plate. The primary pawl disengagement plate is mechanically coupled to the handle such that the handle may be rotated around the cogwheel to a point that the primary pawl disengagement plate contacts the spring-loaded primary pawl and causes it to disengage from the cogwheel. At the same time that the primary pawl is disengaged from the cogwheel teeth by the primary pawl disengagement plate, the handle pawl is similarly disengaged from the cogwheel teeth via contact with a handle pawl disengagement plate. Advantageously, the ratcheting device may be transitioned between a ratcheting state and a free-to-rotate state with only a single hand of the user and without requiring the handle to travel beyond a 180-degree arc of motion.

An image-capturing device includes a camera and a rotating mechanism for orienting the camera in multiple directions. The rotating mechanism includes a motor; a driving gear; a first transmission module including a first input gear, which is selectively engaged with and transmitted to rotate by the driving gear at a first position, and transmitting the camera to rotate in a first direction with rotation of the first input gear; a second transmission module including a second input gear, which is selectively engaged with and transmitted to rotate by the driving gear at a second position, and transmitting the camera to rotate in a second direction with rotation of the second input gear; and a clutch mechanism including a clutch device for driving the driving gear to switch between the first position and the second position. The clutch device includes a solenoid.

Based on the traditional shimbari principle, new methods for precise positioning and support of shimbari rods utilizing a modular aluminum framing system have been developed. With these innovations, a wide range of three-dimensional works of art can be treated, including large-scale sculptures with complex contours and irregular surfaces. These methods and systems include easily adaptable shimbari clamping devices and pivot mounts developed by a team of conservators and an industrial designer-fabricator in the Department of Objects Conservation at the Metropolitan Museum of Art.

Based on the traditional shimbari principle, new methods for precise positioning and support of shimbari rods utilizing a modular aluminum framing system have been developed. With these innovations, a wide range of three-dimensional works of art can be treated, including large-scale sculptures with complex contours and irregular surfaces. These methods and systems include easily adaptable shimbari clamping devices and pivot mounts developed by a team of conservators and an industrial designer-fabricator in the Department of Objects Conservation at the Metropolitan Museum of Art.

An AIDC device cradle includes a movable stand having a post, base plate, and an axle head. A cradle tray is rotatably attached to the axle head via a pivot pin. The cradle tray is configured to receive and accommodate an AIDC device case with an AIDC device. A plurality of locking holes and slots are provided to lock the AIDC device case in position and secure the AIDC device within the device cradle. Integrated charging options are provided. An opening or viewing port is provided on both the AIDC device case and cradle tray enabling the AIDC device scanner to be operational in a downward position.

An AIDC device cradle includes a movable stand having a post, base plate, and an axle head. A cradle tray is rotatably attached to the axle head via a pivot pin. The cradle tray is configured to receive and accommodate an AIDC device case with an AIDC device. A plurality of locking holes and slots are provided to lock the AIDC device case in position and secure the AIDC device within the device cradle. Integrated charging options are provided. An opening or viewing port is provided on both the AIDC device case and cradle tray enabling the AIDC device scanner to be operational in a downward position.